Optical amplification repeater and optical amplification repeating and transmitting system

ABSTRACT

Light signals of first to n-th bands amplified en bloc undergo proper attenuation through an adjustable optical attenuator in conformance with attenuation in an optical fiber connected to input of an optical amplifying repeater apparatus, whereon the light signals are demultiplexed or separated into individual bands and amplified by first to n-th fixed-gain optical amplifiers (# 1 , . . . , #n) each having a high fixed gain in the respective bands to be subsequently multiplexed by an optical multiplexer and then sent out onto a transmission line. A monitoring light branching device extracts a part of light power of a specific monitoring wavelength, which is then fed to an adjustable attenuator control circuit which controls the attenuation factor of the adjustable optical attenuator so that the light power of the specific wavelength remains constant. The gain of the optical amplifying repeater apparatus at the specific wavelength can thus be determined. By employing as the optical amplifying medium a substantially homogeneous medium, the gain for the other wavelengths can be fixed. The optical amplifying repeater apparatus whose gain is essentially independent of the change in the number of the wavelengths can thus be realized.

TECHNICAL FIELD

The present invention relates to an optical amplifying repeaterapparatus implemented by using as a repeater an optical amplifier whichis constituted by employing an optical fiber doped with laser activatingsubstance(s) such as rare-earth element(s), transition metal(s) or thelike and also relates to an optical amplifying/repeating transmissionsystem in which the optical amplifying repeater apparatuses are made useof.

BACKGROUND TECHNIQUES

When compared with the conventional optical repeater having 3R(Reshaping, Retiming, Regenerating) functions known heretofore, theoptical fiber amplifier has desirable features such as independency onthe transmission rate, susceptibility to simplified implementation ofthe repeater, possibility of implementation with large capacity owing tothe wavelength multiplexing capability and others. Thus, the opticalfiber amplif ier is expected to promise a key component which is capableof enhancing flexibility of the optical communication system. Inparticular, in an optical network in which the wavelength multiplexingtechnique is adopted, it is possible to achieve remarkableeconomization.

As the conventional or prior art optical amplifying repeater apparatusof the type mentioned above, there can be mentioned, for example, theone disclosed in “OPTICAL AMPLIFIERS AND THEIR APPLICATION”, PP.280-283, 1998. FIG. 12 is a block diagram showing the prior art opticalamplifying repeater apparatus disclosed in the above-mentionedpublication.

In FIG. 12, reference numerals 1; 4 denote optical amplifiers each offixed gain type for amplifying en bloc light signals of wavelengths λ1to λn, numeral 3 denotes an adjustable optical attenuator, numeral 77denotes an optical branching device for extracting a part of outputpower, numeral 6 denotes an optical attenuator control circuit forcontrolling the adjustable optical attenuator, numerals 501; 506 denoteoptical amplifiers, respectively, each implemented by making use of anerbium-doped fiber or the like, numerals 502 and 507 denote pumpinglight sources, respectively, numerals 503, 504, 508 and 509 denoteoptical branching devices for extracting parts of power of the lightsignals inputted thereto, respectively, and reference numerals 505 and510 denote pumping light source control circuits for controlling thepumping light sources, respectively.

Next, description will be made of operation of the optical amplifyingrepeater apparatus. The wavelength-multiplexed light signals λ1 to λn asinputted are first amplified by the fixed-gain optical amplifier 1 witha predetermined gain G0 and subsequently undergo attenuation with apredetermined attenuation factor through the adjustable opticalattenuator 3. The wavelength-multiplexed light signals outputted fromthe adjustable optical attenuator 3 are again amplified by thefixed-gain optical amplifier 4 with a predetermined gain G1 to beultimately outputted by way of the optical branching device 77. In thatcase, a part of the output signal is extracted through the opticalbranching device 77 and detected by the optical attenuator controlcircuit 6, which circuit is so designed as to control the factor ofattenuation effectuated by the adjustable optical attenuator 3 so thatthe part of the output light signal extracted through the opticalbranching device 77 assumes a predetermined value. In this manner, theoverall or total output power of the optical amplifying repeaterapparatus is maintained at a constant value. In the case where thenumber of the wavelengths is constant, the output powers of therespective wavelengths can be maintained constant on awavelength-by-wavelength basis, rendering it possible to realize idealoperation.

At this juncture, operation of the fixed-gain optical amplifier 1 willbe described in detail. Input/output powers to/from the fixed-gainoptical amplifier 1 are monitored through the optical branching devices503 and 504, respectively, wherein the pumping light source controlcircuit 505 controls the pumping light source 102 such that the ratiobetween the input and output powers of the fixed-gain optical amplifiercan be maintained to be constant. In this way, the gain of thefixed-gain optical amplifier 1 is held constant. Similar operation isperformed for the fixed-gain optical amplifier 4 as well.

Furthermore, FIG. 13 shows in a block diagram another prior art opticalamplifying repeater apparatus which is disclosed, for example, in“OPTICAL AMPLIFIERS AND THEIR APPLICATIONS”, MD1, 1998. This opticalamplifying repeater apparatus is so arranged as to perform not onlyamplification of the light signals of wavelengths λ1 to λn but also gaincontrol for the optical repeater on the basis of monitoring informationcarried by a monitoring light signal λs sent from terminal equipment. InFIG. 13, reference numeral 11 denotes an optical branching device forseparating the monitoring light signal λs from the light signals ofwavelengths λ1 to λn, and reference numeral 17 denotes a monitoringlight receiver.

Next, description will turn to operation of the optical amplifyingrepeater apparatus described above. The wavelength-multiplexed lightsignals λ1 to λn as inputted are first amplified by the fixed-gainoptical amplifier 1 with a predetermined gain G0 to subsequently undergoattenuation with a predetermined attenuation factor through theadjustable optical attenuator 3. The wavelength-multiplexed lightsignals outputted from the adjustable optical attenuator 3 are againamplified by the fixed-gain optical amplifier 4 with a predeterminedgain G1 to be outputted via the optical branching device 77. A part ofthe output signal is extracted through the optical branching device 77and detected by the optical attenuator control circuit 6, which circuitis also so designed as to control the attenuation effectuated by theadjustable optical attenuator 3 so that the part of the output signalextracted through the optical coupling device 77 assumes a predeterminedvalue. In this manner, the overall total output power of the opticalamplifying repeater apparatus is maintained at a constant value orlevel. So long as the number of the wavelengths is constant, the outputpowers of the respective wavelengths can be maintained constant on awavelength-by-wavelength basis, whereby ideal operation can be ensured.The information about the number of wavelengths is contained in themonitoring information carried by the monitoring light signal λs sentout from the terminal equipment and thus inputted to the opticalattenuator control circuit 6 after reception by the monitoring lightreceiver 17.

In the optical amplifying repeater apparatus of the structures describedabove, a part of the total output power is extracted by the opticalbranching device 77 for the purpose of controlling the adjustableoptical attenuator 3 so that the output power can be maintained to beconstant. As a result of this, very troublesome procedure is requiredfor coping with increase or decrease of the number of wavelengths. Morespecifically, because the total output power of the optical amplifyingrepeater apparatus depends on the number of wavelengths, there arisesnecessity of messaging in advance to the optical attenuator controlcircuit 6 the value which the light power extracted through the opticalbranching device 77 is to assume, when the number of wavelengths ischanged. Consequently, in the case where one of thewavelength-multiplexed light signals of wavelengths λ1 to λn is nottransmitted due to some failure in sender equipment, by way of example,the messaging procedure such as mentioned above will not be in time forcoping with the change of the number of wavelengths, thus bringing aboutcorresponding changes in the powers of the other wavelengths, which ofcourse will exert adverse influence to the quality of communication.

An object of the present invention is to solve the problem such asmentioned above and to provide an optical amplifying repeater apparatuswhich can positively protect the quality of communication from beingdegraded even when the powers of the other wavelengths change andfurther provides an optical amplifying/repeating transmission systemwhich can maintain the system gain to be constant independently of thelight signal power as inputted or the number of wavelengths thereof.

DISCLOSURE OF THE INVENTION

An optical amplifying repeater apparatus which the present inventionconcerns includes an input port to which a plurality of light signalsmultiplexed in wavelength are inputted, a first fixed-gain opticalamplifier for amplifying the wavelength-multiplexed light signalsinputted through the input port with a predetermined gain, an adjustableoptical attenuator for attenuating the wavelength-multiplexed lightsignals by a predetermined factor after amplification through the firstfixed-gain optical amplifier, an optical demultiplexer fordemultiplexing the wavelength-multiplexed light signals outputted fromthe adjustable optical attenuator into a plurality of individual lightsignals of discrete wavelengths, respectively, fixed-gain opticalamplifiers #1; #n for amplifying the plurality of individualwavelength-demultiplexed light signals outputted from the opticaldemultiplexer with a predetermined gain, a monitoring light branchingdevice connected to one of outputs of the second fixed-gain opticalamplifiers #1; #n for extracting a part of a specific monitoring lightsignal, an optical multiplexer for multiplexing the individual lightsignals outputted from the second fixed-gain optical amplifiers #1; #n,respectively, for thereby outputting multiplexed light signals, and anadjustable attenuator control circuit for detecting output power of themonitoring light branching device to thereby control the attenuationfactor of the optical attenuator so that the detected output powerassumes a constant value.

Further, an optical amplifying repeater apparatus which the presentinvention concerns includes an input port to which a plurality of lightsignals multiplexed in wavelength are inputted, a first fixed-gainoptical amplifier for amplifying the wavelength-multiplexed lightsignals inputted through the input port with a predetermined gain, anoptical demultiplexer connected to output of the first fixed-gainoptical amplifier for demultiplexing the wavelength-multiplexed lightsignals into a plurality of individual light signals of respectivewavelengths, adjustable optical attenuators #1; #n for attenuating theoutputs of the optical demultiplexers, respectively, by a predeterminedfactor, fixed-gain optical amplifiers #1; #n for amplifying theplurality of light signals outputted from the adjustable opticalattenuators with a predetermined gain, monitoring light branchingdevices connected to outputs of the fixed-gain optical amplifiers #1; #nfor extracting parts of specific monitoring light signals #1; #n,respectively, an optical multiplexer for multiplexing the outputs of thefixed-gain optical amplifiers #1; #n to thereby output multiplexed lightsignals, and adjustable attenuator control circuits #1; #n for detectingoutput powers of the monitoring light branching devices to therebycontrol the attenuation factor of the optical attenuators so that eachof the detected output powers assumes a constant value.

In the optical amplifying repeater apparatus described above, the firstfixed-gain optical amplifier includes an optical fiber serving as atransmission line, a pumping light source for iinducing stimulated Ramanamplifying action internally of the optical fiber in wavelength bands ofthe plurality of wavelength-multiplexed light signals, and an opticalcoupling device for coupling the output of the pumping light source withthe plurality of wavelength-multiplexed light signals.

Further, in the optical amplifying repeater apparatus described above,the first fixed-gain optical amplifier includes an optical fiber dopedwith a rare-earth element or alternatively a transition metal, a pumpinglight source for inducing amplifying action under stimulated emissioninternally of the optical fiber in wavelength bands of the plurality ofwavelength-multiplexed light signals, and an optical coupling device forcoupling the output of the pumping light source with the plurality ofwavelength-multiplexed light signals, wherein the optical fiber dopedwith the rare-earth element or alternatively the transition metal isoperative in an unsaturated region.

Further, in the optical amplifying repeater apparatuses described above,the fixed-gain optical amplifier #1; #n includes an optical amplifyingunit composed of an optical fiber doped with a rare-earth element oralternatively a transition metal and a pumping light source forstimulating the rare-earth element or alternatively the transition metalto thereby bring about stimulated emission, a compensating light sourcefor generating compensating light having a wavelength within anamplified wavelength band of the optical amplifying unit, ancompensating light coupling device for coupling the compensating lightwith the plurality of wavelength-multiplexed light signals, acompensating light branching device for separating mutually thecompensating light and the plural wavelength-multiplexed light signalscontained in the output of the optical amplifying unit, and acompensating light control circuit for controlling output power of thecompensating light source such that ratio between power of thecompensating light outputted from the compensating light branchingdevice and power of the compensating light outputted from thecompensating light source assumes a predetermined standard value.

Furthermore, in the optical amplifying repeater apparatuses describedabove, the fixed-gain optical amplifier #1; #n includes an opticalamplifying unit composed of an optical fiber doped with a rare-earthelement or alternatively a transition metal and a pumping light sourcefor stimulating the rare-earth element or alternatively the transitionmetal to thereby bring about stimulated emission, and a compensatinglight control circuit for controlling output power of the compensatinglight source such that power of spontaneously emitted light outputtedfrom the optical amplifying unit assumes a predetermined standard value.

Furthermore, in the optical amplifying repeater apparatuses describedabove, the fixed-gain optical amplifier#1; #n includes an adjustableoptical attenuator #1′; #n′ inserted at an input or output side, wherebya means for changing the attenuation factor of the adjustable opticalattenuator #1′; #n′ in dependence on ambient temperature is implemented.

Additionally, an optical amplifying/repeating transmission system whichthe present invention concerns includes a plurality of transmitters forsending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system further includes a control signal superposing meansfor superposing a control signal of a specific frequency onto one of theplural light signals, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant.

Moreover, an optical amplifying/repeating transmission systemwhich thepresent invention concerns includes a plurality of transmitters forsending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system further includes a control signal generating meansfor modulating one of the plural light signals with a control signal ofa specific frequency, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant.

Besides, an optical amplifying/repeating transmission system which thepresent invention concerns includes a plurality of transmitters forsending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system includes a control signal superposing means forsuperposing a control signal of a specific frequency onto one of theplural light signals, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant, a monitorsignal transmitting means for supplying transmission level of thecontrol signal to the optical repeater, and a monitor/control means forreceiving a monitoring signal supplied from the monitor signaltransmitting means to thereby enable the optical repeater gain controlmeans to operate when the level of the control signal is normal whiledisabling operation of the optical repeater gain control means with thegain thereof being held when the level of the control signal isabnormal.

Besides, an optical amplifying/repeating transmission system accordingto the present invention includes a plurality of transmitters forsending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system further includes a control signal generating meansfor modulating one of the plural light signals with a control signal ofa specific frequency, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant, a monitorsignal transmitting means for supplying transmission level of thecontrol signal to the optical repeater, and a monitor/control means forreceiving a monitoring signal supplied from the monitor signaltransmitting means to thereby enable the optical repeater gain controlmeans to operate when the level of the control signal is normal whiledisabling operation of the optical repeater gain control means with thegain thereof being held when the level of the control signal isabnormal.

In the optical communication system described above, the opticalrepeater gain control means is composed of an adjustable opticalattenuator and a means for controlling the adjustable opticalattenuator.

Further, in the optical communication system described above, thecontrol signal has a frequency higher than 100 kHz inclusive thereof.

Furthermore, in the optical communication system described above, themonitoring signal has a wavelength shorter than those sent out from theplurality of transmitters.

Moreover, an optical amplifying repeater apparatus for amplifying aplurality of wavelength-multiplexed light signals according to thepresent invention includes a first fixed-gain optical amplifier foramplifying a plurality of wavelength-multiplexed light signals inputtedthereto with a predetermined gain, a control light signal branchingdevice for extracting a part of power of a control wavelength containedin the output of the first fixed-gain optical amplifier, an adjustableoptical attenuator for attenuating the output of the first fixed-gainoptical amplifier by a predetermined factor, an adjustable attenuatorcontrol circuit for detecting output power of the control light signalbranching device to thereby control the attenuation factor of theadjustable optical attenuator so that the detected output power remainsconstant, and a second fixed-gain optical amplifier connected to outputof the adjustable optical attenuator for amplifying the pluralwavelength-multiplexed light signal inputted to the second fixed-gainoptical amplifier with a predetermined gain.

In the optical amplifying repeater apparatus described above furtherincludes an output breaking circuit for stopping amplifying function ofthe second fixed-gain optical amplifier upon detection of disappearanceof output of the control light signal branching device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing a configuration or structure of anoptical amplifying repeater apparatus according to a first embodiment ofthe present invention,

FIG. 2 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a second embodiment of the invention,

FIG. 3 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a third embodiment of the invention,

FIG. 4 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a fifth embodiment of the invention,

FIG. 5 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a sixth embodiment of the invention,

FIG. 6 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a seventh embodiment of the invention,

FIG. 7 is a view for illustrating energy levels of a doped fiber,

FIG. 8 is a block diagram showing a configuration or structure of anoptical amplifying/repeating transmission system according to an eighthembodiment of the invention,

FIG. 9 is a block diagram showing a structure of an opticalamplifying/repeating transmission system according to a ninth embodimentof the invention,

FIG. 10 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a twelfth embodiment of the invention,

FIG. 11 is a block diagram showing a structure of an optical amplifyingrepeater apparatus according to a thirteenth embodiment of theinvention,

FIG. 12 is a block diagram showing a structure of a conventional opticalamplifying repeater apparatus known heretofore, and

FIG. 13 is a block diagram showing a structure of another conventionaloptical amplifying repeater apparatus.

BEST MODES FOR CARRYING OUT THE INVENTION Embodiment 1

FIG. 1 is a block diagram showing a configuration or structure of anoptical amplifying repeater apparatus according to a first embodiment ofthe present invention. In FIG. 1, reference numeral 1 denotes a firstfixed-gain optical amplifier, numeral 2 denotes an opticaldemultiplexer, numeral 3 denotes an adjustable optical attenuator,numerals 4 a; 4 b denote fixed-gain optical amplifiers #1-#n, numeral 5denotes a monitoring light branching device, numeral 6 denotes anadjustable attenuator control circuit, and reference numeral 7 denotesan optical multiplexer.

Next, operation of the optical amplifying repeater apparatus will bedescribed. Referring to FIG. 1, the first fixed-gain optical amplifier 1is designed to amplify wavelength-multiplexed light signals of n bands,i.e., wavelengths λ11 to λ1n (first band), λ21 to λ2n (secondband), . .. , λn1 to λnn (n-th band) with a predetermined gain.

In the present state of the art, such a system has already beendeveloped for practical applications in which two bands, e.g. a firstband of 1530 to 1560 nm and a second band of 1570 to 1600 nm, are madeavailable each for transmitting 32 light waves. As the first fixed-gainoptical amplifier 1, a fiber amplifier doped with erbium or the like canbe employed. The light signals of the first to n-th bands (#1, . . . ,#n) amplified en bloc by the first fixed-gain optical amplifier 1 arethen attenuated by the adjustable optical attenuator 3 properly inconformance to the attenuation which these light signals has undergoneduring transmission through an optical fiber connected to an input portof the optical amplifying repeater apparatus to be subsequentlyseparated or multiplexed into respective bands by means of the opticaldemultiplexer 2. The light signals of the discrete bands resulting fromthe demultiplexing operation of the optical demultiplexer 2 are thenamplified on a band-by-band basis by the fixed-gain optical amplifiers#1 to #n, respectively, each of which has a high fixed gain, to besubsequently multiplexed by means of the optical multiplexer 7, theoutput of which is sent onto a transmission line.

The monitoring light branching device 5 serves to extract a monitoringlight signal of a specific wavelength, e.g. a part of light power of thewavelength λ1n, which is then supplied to this adjustable attenuatorcontrol circuit 6. In response to the monitoring light signal, theadjustable attenuator control circuit 6 controls the attenuation factorof the adjustable optical attenuator 3 so that the light power of thewavelength λ1n becomes constant. Through the operation mentioned above,the gain of the optical amplifying repeater apparatus for the particularor specific wavelength can be determined. Accordingly, by employing asthe optical amplifying medium a substantially homogeneous medium such asa semiconductor amplifier, an optical fiber doped with rare-earthelement(s) or the like, the gain of the optical amplifying repeaterapparatus for the other wavelengths can be fixed as well. Thus, therecan be realized the optical amplifying repeater apparatus whose gainexhibits essentially no dependency on the change of the number ofwavelengths. In this conjunction, it is conceivable that for the purposeof further enhancing the accuracy of the gain control described above,such a systemmay be adopted in which a tone signal of a specificfrequency is superposed on the monitoring light signal, and the tonesignal is extracted by an electric filter which is incorporated in theadjustable attenuator control circuit 6 for the purpose of suppressingthe influence of noise.

Embodiment 2

FIG. 2 is a block diagram showing a configuration of the opticalamplifying repeater apparatus according to a second embodiment of theinvention. In FIG. 2, reference numeral 1 denotes a first fixed-gainoptical amplifier, numeral 2 denotes an optical demultiplexer, numerals3 a; 3 b denote adjustable optical attenuators #1-#n, respectively,numerals 4 a; 4 b denote fixed-gain optical amplifiers #1-#n,respectively, numerals 5 a; 5 b denote monitoring light branchingdevices #1-#n, respectively, numerals 6 a; 6 b denote adjustableattenuator control circuits #1-#n, respectively, and reference numeral 7denotes an optical multiplexer.

Next, operation of the optical amplifying repeater apparatus accordingto the instant embodiment will be described. Referring to FIG. 2, thefirst fixed-gain optical amplifier 1 is designed to amplifywavelength-multiplexed light signals of n bands, i.e., wavelengths 11 toλ1n (first band), λ21 to λ2n (second band), . . . , λn1 to λnn (n-thband) with a predetermined gain.

The light signals of the first to n-th bands amplified en bloc asdescribed above are then demultiplexed or separated into the respectivebands and undergone proper attenuation through the adjustable opticalattenuators 3 a; 3 b, respectively, whereon the individual light signalsare amplified by the first to n-th fixed-gain optical amplifiers (#1, .. . , #n) each having a high fixed gain in the respective bands to besubsequently multiplexed by the optical multiplexer 7 and then sent outonto the transmission line. The adjustable optical attenuators 3 a; 3 b(#1, . . . , #n) are employed for the purpose of compensating fordeviations from the prescribed value of loss brought about duringtransmission through an optical fiber connected to the input port of theoptical amplifying repeater apparatus, as described hereinbefore inconjunction with the first embodiment of the invention.

More specifically, when the loss in the optical fiber connected to theinput port of the optical amplifying repeater apparatus is smaller thanthe prescribed value by D [dB], the attenuation factor of the adjustableoptical attenuators 3 a; 3 b, respectively, are set to D [dB]. In thisconjunction, it is noted that in case the wavelength ranges of the bands#1, . . . , #n are wide, there may arise such situation that theattenuation factors to be set for the adjustable optical attenuatorfactors 3 a; 3 b (#1, . . . , #n), respectively, differ from one toanother because the loss brought about during transmission through theoptical fiber connected to the input port of the optical amplifyingrepeater apparatus will exhibit dependency on the wavelengths.Accordingly, in the case of the optical amplifying repeater apparatusaccording to the second embodiment of the invention, there are providedthe adjustable optical attenuators 3 a; 3 b (#1, . . . , #n) incorrespondence to the discrete bands (#1, . . . , #n), respectively.

The monitoring light branching devices 5 a; 5 b (#1, . . . , #n) areeach so designed as to extract specific monitoring light signals, e.g.parts of light power of the wavelengths λ1n, . . . , λnn, which are thenfed to the adjustable attenuator control circuits 6 a; 6 b (#1, . . . ,#n), respectively. The adjustable attenuator control circuits 6 a; 6 bcontrol the attenuation factors of the associated adjustable opticalattenuators 3 a; 3 b (#1, . . . , #n), respectively, so that the lightpowers of the specific wavelengths λ1n, . . . , λnn remain constant.Through the operation mentioned above, the gains of the opticalamplifying repeater apparatus for the monitoring light wavelengths λ1n,. . . , λnn in the specific band can be determined. Thus, by employingas the optical amplifying medium a substantially homogeneous medium suchas a semiconductor amplifier, an optical fiber doped with rare-earthelement(s) or the like, the gains for the other wavelengths can befixed. Thus, there can be implemented the optical amplifying repeaterapparatus whose gain is essentially insusceptible to the change in thenumber of the wavelengths.

Embodiment 3

FIG. 3 is a block diagram showing a configuration or structure of anoptical amplifying repeater apparatus according to a third embodiment ofthe invention. In FIG. 3, reference numeral 8 denotes an optical fiber,numeral 9 denotes an optical coupling device and reference numeral 10denotes a pumping light source. In the figure, components same as orequivalent to those of the optical amplifying repeater apparatusdescribed previous by reference to FIG. 2 are denoted by like referencesymbols, and description thereof is omitted.

Operation of the optical amplifying repeater apparatus according to theinstant embodiment will be described. In the optical amplifying repeaterapparatus now under consideration, the pumping light source 10 sends outpumping light injected to the optical fiber 8 by way of the opticalcoupling device 9 for effectuating the stimulated Raman amplification.Since the stimulated Raman amplifier is difficult to be subjected togain saturation when compared with the semiconductor amplifier and theoptical fiber doped with rare-earth element(s) and is capable ofperforming substantially linear operation up to the output powersubstantially equal to the pumping light power, the stimulated Ramanamplifier is the most suitable amplifying medium to be used as the firstfixed-gain optical amplifier. Thus, ideal operation of the firstfixed-gain optical amplifier 1 can be realized. Operations of the othercomponents shown in FIG. 3 are similar to those of the opticalamplifying repeater apparatus described hereinbefore in conjunction withthe second embodiment of the invention.

Embodiment 4

The optical amplifying repeater apparatus according to the instantembodiment of the invention is implemented in substantially samestructure as that of the third embodiment.

Accordingly, repetitive description will be unnecessary. It shouldhowever be mentioned that the optical amplifying repeater apparatusaccording to the instant embodiment differ from the third embodiment inrespect to the pumping light source 10.

Operation of the optical amplifying repeater apparatus according to theinstant embodiment will be described. According to the teaching of theinvention incarnated in the instant embodiment, the pumping light source10 of sufficiently high rated power is employed so that the opticalfiber 8 doped with rare-earth(s) or transition metal(s) is capable ofperforming amplifying operation in the unsaturated region under theeffect of the stimulated emission in the wavelength bands of pluralwavelength-multiplexed light signals. The optical multiplexer 7 servesfor optically coupling the plural wavelength-multiplexed light signalsmentioned above with the output of the pumping light source 10. In thismanner, by using the pumping light source 10 of sufficiently high outputpower, the gain of the optical amplifying repeater apparatus can bemaintained to be essentially constant.

Embodiment 5

FIG. 4 is a block diagram showing a configuration of an opticalamplifying repeater apparatus according to a fourth embodiment of theinvention. More specifically, this figure shows an exemplary structureof the fixed-gain optical amplifier #1, . . . , #n. In FIG. 4, referencenumeral 61 denotes an optical isolator, numeral 62 denotes an opticalcoupling device serving as a compensating light coupling device, numeral63 denotes an optical fiber doped with rare-earth element(s) ortransition metal(s) (hereinafter referred to as the doped fiber),numeral 64 denotes an optical coupling device, numeral 650 denotes anoptical filter serving as a compensating light branching device forextracting the compensating light, numeral 66 denotes a photodetector,numeral 67 denotes a compensating light control circuit, numeral 68denotes a compensating light source, numeral 69 denotes a compensatinglight monitoring element, numeral 70 denotes a compensating light sourcedriving circuit, numeral 71 denotes a pumping light source, numeral 72denotes a pumping light monitoring element, and reference numeral 73denotes a pumping light source driving circuit.

Parenthetically, it is to be added that the doped fiber 63, the opticalcoupling device 64 and the pumping light source 71 cooperate toconstitute an optical amplifying unit.

Next, description will turn to operation of the apparatus. The dopedfiber employed most conveniently as the fixed-gain optical amplifier #1,. . . , #n is likely to be saturated in the gain. Accordingly, in casethe doped fiber is used as the fixed-gain optical amplifier, someauxiliary circuit will have to be provided in association with thefixed-gain optical amplifier implemented by using the doped fiber.Referring to the figure, the doped fiber 63 is supplied with pumpinglight of a constant level from the optical multiplexer 7 through themedium of the optical coupling device 64. Operation for maintaining thepumping light at a constant level can easily be achieved by monitoringthe output power of the pumping light source by means of the pumpinglight monitoring element 72 and controlling appropriately the level ofthe driving current for the pumping light source by means of the pumpinglight source driving circuit 73.

The compensating light emitted from the compensating light source 68 isinjected into the doped fiber 63 through the optical coupling device 62.The compensating light branching device 650 serves for extracting orfiltering out the amplified compensating light outputted from the dopedfiber 63, wherein the output of the compensating light branching deviceis supplied to the photodetector 66. The output of the photodetector 66in turn is fed to the compensating light control circuit 67 for thepurpose of controlling the compensating light source driving circuit 70so that the ratio between the monitored level outputted from thecompensating light monitoring element 69 and that of the photodetector66 remains constant. Through the operation described above, the gain ofthe fixed-gain optical amplifiers #1, . . . , #n at the wavelength ofthe compensating light can be regulated to be constant. Thus, for thefixed-gain optical amplifier 1 having the homogeneous characteristics,constant gain can be ensured for all the wavelength bands foramplification.

Embodiment 6

FIG. 5 is a block diagram showing a configuration of an opticalamplifying repeater apparatus according to a sixth embodiment of theinvention. More specifically, this figure shows an exemplary structureof the fixed-gain optical amplifier #1, . . . , or #n. In FIG. 5,reference numeral 651 denotes an optical filter for extracting orfiltering out spontaneously emitted light from the doped fiber in apredetermined wavelength band. Incidentally, in FIG. 5, components sameas or equivalent to those mentioned hereinbefore in conjunction with theoptical amplifying repeater apparatus shown in FIG. 4 are denoted bylike reference symbols and description thereof is omitted.

In operation, the optical filter 651 filters out the spontaneouslyemitted light from the doped fiber 63 in a predetermined wavelengthband, the output of the optical filter 651 being inputted to thephotodetector 66. In the case of the fixed-gain optical amplifieraccording to the instant embodiment, the compensating light controlcircuit 67 is so designed as to control the compensating light sourcedriving circuit 70 so that the output of the photodetector 66 ismaintained to be constant. In general, the gain of the doped fiber 63 isin proportion to the power of spontaneously emitted light. Thus, withthe arrangement described above, constant gain can be ensuredindependently of the number of the signal wavelengths injected orinputted to the doped fiber 63.

Embodiment 7

FIG. 6 is a block diagram showing a configuration of the opticalamplifying repeater apparatus according to a seventh embodiment of theinvention. More specifically, this figure shows an exemplary structureof the fixed-gain optical amplifier #n. In FIG. 6, reference numeral 77denotes adjustable attenuator and numeral 78 denotes an adjustableattenuator control circuit. In FIG. 6, components same as or equivalentto those mentioned hereinbefore in conjunction with the opticalamplifying repeater apparatus shown in FIG. 4 are denoted by likereference symbols and description thereof is omitted.

FIG. 7 is an energy level diagram of a doped fiber. At first,description will be made of the temperature dependence characteristic(s)of the gain of the doped fiber 63. The gain of the doped fiber is inproportion to density difference between the pumped or stimulated stateor level at which the laser transition takes place and the ground statelevel. In general, the stimulated state level and the ground state levelcan each be divided finely into sublevels in view of the Stark effect.

Referring to FIG. 7, the temperature dependency of the gain for thelongest wave is considered. The gain for the longest wave is determinedby the density difference between the lowest energy sublevel in thepumped or excited state and the highest energy sublevel in the groundstate. Since the density distribution between these sublevels isdetermined by the Boltzmann's distribution, the gain for the longestwave is low when temperature is high while it is high when thetemperature is low. Thus, the temperature dependency of thegain-wavelength characteristic becomes remarkable for the longest wavein a given band.

Turning back to FIG. 6, with a view to compensating for the temperaturedependency of the gain described above, the adjustable attenuatorcontrol circuit 78 is designed to control the attenuation factor of theadjustable attenuator 77 such that it is set to a small value at a hightemperature while being set to a large value at a low temperature. As aresult of this, the gain of the doped fiber 63 for the longest wavedecreases as the temperature increases while the former increases as thelatter decreases, whereby the gain-wavelength characteristic in thelongest wave region can be maintained to be substantially constant.Besides, the absolute value of the gain can be held essentiallyconstant.

Embodiment 8

FIG. 8 is a block diagram showing a configuration of an opticalamplifying/repeating transmission system according to an eighthembodiment of the invention. In FIG. 8, reference numerals 101 a; 101 bdenote terminal stations, numerals 102 a; 102 b denote opticalrepeaters, respectively, numerals 103 a, . . . , 103 c denote opticalfibers, respectively, numerals 104, . . . , 106 denote senders ortransmitters, respectively, numeral 107 denotes an optical multiplexer,numeral 108 denotes a remote monitor/control circuit serving as acontrol signal generating means or a control signal superposing means,numerals 112; 114 denote fixed-gain optical amplifiers, respectively,numeral 113 denotes an adjustable optical attenuator, numeral 115denotes an optical filter or optical branching device serving as acontrol signal level detecting means, numeral 116 denotes an adjustableoptical attenuator control circuit serving as an optical repeater gaincontrol means, numeral 123 denotes an optical demultiplexer, andreference numerals 124, . . . , 126 denote receiving equipment orreceivers.

Next, description will turn to operation of the opticalamplifying/repeating transmission system. At the terminal station 101 a,a plurality of transmitters 104, . . . , 106 serve for converting theinformation to be transmitted into light signals λ1, . . . , λn, whichthen undergo wavelength-multiplexing operation through the opticalmultiplexer 107 to be sent out onto the optical fiber 103 a. The remotemonitor/control circuit 108 serves to modulate the light intensity ofthe output of the transmitter 106 with a specific frequency fs. To thisend, the modulation factor (percentage modulation) is ordinarily set atseveral percent or lower so that no adverse influence is executed to theinput port. At the optical repeater 102 a, the receivedwavelength-multiplexed signal is first amplified by the fixed-gainoptical amplifier 112 with a predetermined gain G0 and thereafterattenuated by the adjustable optical attenuator 113 with a predeterminedfactor L, whereon the wavelength-multiplexed signal outputted from theadjustable optical attenuator is again amplified by the fixed-gainoptical amplifier 114 with a predetermined gain G1.

The attenuation factor L is determined as follows. The optical filter115 extracts a part of the power of the wavelength λn from the amplifiedwavelength-multiplexed signal, the output of the optical filter beinginputted to the adjustable optical attenuator control circuit 116, whichresponds thereto by controlling the attenuation factor L of theadjustable optical attenuator 113 so that the power of the frequency fscontained in the extracted power of the wavelength λn becomes constant.In this way, the repeater gain for the wavelength λn can be maintainedconstant independently of the number of wavelengths. In general, theoptical amplifying medium employed for amplifying thewavelength-multiplexed light signal such as e.g. the optical fiberamplifier doped with rare-earth element(s), semiconductor opticalamplifier or the like exhibits homogeneous characteristics. This meansthat the gain fixed for a given wavelength is also fixed for the otherwavelengths. Thus, there can be realized stable amplificationcharacteristics which exhibit no dependency on the number ofwavelengths.

In the case of the optical amplifying/repeating transmission systemaccording to the instant embodiment of the invention, the remotemonitor/control circuit 108 which serves as the control signalgenerating means is designed to generate the control signal bymodulating the light intensity outputted from the transmitter 106. Itshould however be understood that the remote monitor/control circuit 108may be so arranged as to generate a control signal of a specificfrequency and superpose it on a given one of the plural light signals(control signal superposing means).

Embodiment 9

FIG. 9 is a block diagram showing a configuration of an opticalamplifying/repeating transmission system according to a ninth embodimentof the invention. In FIG. 8, reference numeral 108 denotes a remotemonitor/control circuit, numeral 109 denotes an optical coupling device,numeral 110 denotes an optical branching device, numeral 111 denotes alight signal branching device, numeral 118 denotes a monitor/controlcircuit, numeral 119 denotes a monitoring signal sender, numeral 120denotes an optical coupling device, numeral 121 denotes an opticalbranching device, and reference numeral 126 denotes an opticalattenuator control circuit).

Operation of the optical amplifying/repeating transmission system willnow be described. The remote monitor/control circuit 108 serves not onlyfor modulation of the light signal intensity outputted from thetransmitter 106 with the frequency fs but also for measuring the powerof the light signal of wavelength λn contained in thewavelength-multiplexed signal and branched by the optical branchingdevice 110, to thereby superpose the information carried by the lightsignal of the wavelength λn on the monitoring light signal λs. Thus,theremote monitor/control circuit of the optical amplifying/repeatingtransmission system according to the instant embodiment of the inventionserves not only as the control signal generating means but also as thecontrol signal superposing means and the monitor signal transmittingmeans. The optical coupling device 109 is designed to multiplex themonitoring light signal λs with the light signals with low loss. In theoptical repeater 102 a, monitoring light signal )s is extracted throughthe light signal branching device 111 and received by the opticalrepeater gain control means to be subsequently supplied to the monitorcontrol/circuit 118, which in turn is so designed as to controloperation of the gain control system which is constituted by theadjustable optical attenuator 113 and the adjustable optical attenuatorcontrol circuit 116. More specifically, the monitor/control circuitallows operation of the gain control system so long as the power of thelight signal of wavelength λn is normal while suspending the operationof the gain control system by holding the attenuation factor of theadjustable optical attenuator 113 to be constant when the power of thewavelength λn is abnormal. By virtue of this arrangement, the gain ofthe optical repeater 102 a is prevented from being set to an erroneousvalue even when the power of the light signal of wavelength λn lowersdue to so-called age deterioration or the like cause.

Embodiment 10

The frequency fs with which the light signal intensity outputted fromthe transmitter 106 is modulated by the remote monitor/control circuit108 should be set to a large value at which variation in the gain of thefixed-gain optical amplifiers 112; 114 does not occur. Morespecifically, in the case of the optical fiber doped with rare-earthelement(s) used conventionally as the optical amplifying medium in whicherbium is employed as the laser medium, the life of light quantum orphoton is 10 s. Accordingly, it is sufficient to set the frequency f0 atseveral tens kHz or higher. Thus, according to the teaching of theinvention incarnated in the tenth embodiment, the frequency fs is set at100 kHz or higher in order to ensure stable amplificationcharacteristics for the fixed-gain optical amplifier 112; 114 bypreventing variation of the gains of these amplifiers.

Embodiment 11

In conjunction with the tenth embodiment, description has been made asto the measure for coping with such situation that the power of lightsignal of wavelength λn employed as the control light for controllingthe gain of the optical repeater becomes anomalous. On the other hand,it is also conceivable that the light signal of the wavelength λn issuddenly interrupted for some reason. In that case, there arisesnecessity of messaging the sudden interruption even to the terminalstations 101 a and 101 b with the monitoring light signal As before thelight signal of wavelength λn interrupted reaches at the terminalstations. In this conjunction, it is noted that the optical fibers 103a, . . . , 103 c present a group speed which differs in dependence onthe wavelengths. By way of example, a light signal of 1.3 μm inwavelength propagates more speedily that a light signal of 1.55 μm inwavelength by 2.2 ns per kilometer. Accordingly, by setting thewavelength of the monitoring light signal to e.g. 1.3 μm which isshorter than that of light signal used ordinarily whose wavelength is1.15 μm, the operating state control of the gain control system can beperformed owing to the availability of the monitoring light signal λseven in the event that the power of wavelength λn is interrupted forsome reason.

Embodiment 12

FIG. 10 is a block diagram showing a configuration of an opticalamplifying repeater apparatus according to a twelfth embodiment of theinvention. In FIG. 10, reference numeral 603 denotes a control lightsignal branching device for extracting a part of the power of a controllight signal employed for controlling the gain of the optical amplifyingrepeater apparatus.

Operation of the optical amplifying repeater apparatus according to theinstant embodiment of the invention will be described. The inputtedwavelength-multiplexed signals λ1; λn are first amplified by the firstfixed-gain optical amplifier 1 with a predetermined gain G0 to besubsequently inputted to the control light signal branching device 603,which is designed to extract a part of the power of the control lightλc. Major parts of the powers of the light signals of the otherwavelengths and that of the control light λc are inputted to theadjustable optical attenuator 3 with low loss. On the other hand, theadjustable attenuator control circuit 6 is designed to control theattenuation factor of the adjustable optical attenuator 3 so that thepower outputted from the control light signal branching device 603remains constant. The wavelength-multiplexed-light signals λ1; λnoutputted from the adjustable optical attenuator 3 are again amplifiedby the second fixed-gain optical amplifier 4 with a constant gain G1.Through the operation described above, the gain of the opticalamplifying repeater apparatus for a specific wavelength can bedetermined. Thus, by using a substantially homogeneous medium such asthe semiconductor amplifier, the optical fiber doped with rare-earthelement(s) or the like as the optical amplifying medium, the gain forthe other wavelengths is fixed. In other words, there can be realizedthe optical amplifying repeater apparatus having the gain which isindependent of change of the number of wavelengths.

The monitor/control circuit 17 plays the roll described below. When thepower of the received light signal becomes lower than a predeterminedvalue, the monitor/control circuit 17 stops the amplifying action of thefirst fixed-gain optical amplifier 1 and the second fixed-gain opticalamplifier 4 while suppressing surge phenomenon which takes place uponrecovery of the received signal.

Embodiment 13

FIG. 11 is a block diagram showing a configuration of an opticalamplifying repeater apparatus according to a thirteenth embodiment ofthe invention. In FIG. 11, reference numeral 26 denotes an opticalattenuator control circuit designed to serve also as the output breakcircuit. In the case of the optical amplifying repeater apparatusaccording to the instant embodiment of the invention, the opticalattenuator control circuit 26 is also imparted with the function forcontrolling the amplifying action of the second fixed-gain opticalamplifier 4.

In operation of the optical amplifying repeater apparatus, the opticalattenuator control circuit 26 serves not only for controlling theattenuation factor of the adjustable optical attenuator 3 so that thepower outputted from the control light signalbranchingdevice 603 isconstantbut also forstopping the amplification operation of the secondfixed-gain optical amplifier 4 when the power outputted from the controllight signal branching device 603 becomes lower than a predeterminedlevel (output break circuit). By virtue of this function, it is possibleto prevent the output power of the second fixed-gain optical amplifier 4from increasing abnormally even when the control light is interruptedfor some cause.

INDUSTRIAL APPLICABILITY

The optical amplifying repeater apparatus according the presentinvention includes an input port to which a plurality of light signalsmultiplexed in wavelength are inputted, a first fixed-gain opticalamplifier for amplifying the wavelength-multiplexed light signalsinputted through the input port with a predetermined gain, an adjustableoptical attenuator for attenuating the wavelength-multiplexed lightsignals by a predetermined factor after amplification through the firstfixed-gain optical amplifier, an optical demultiplexer fordemultiplexing the wavelength-multiplexed light signals outputted fromthe adjustable optical attenuator into a plurality of individual lightsignals of discrete wavelengths, respectively, fixed-gain opticalamplifiers #1; #n for amplifying the plurality of individualwavelength-demultiplexed light signals outputted from the opticaldemultiplexer with a predetermined gain, a monitoring light branchingdevice connected to one of outputs of the second fixed-gain opticalamplifiers #1; #n for extracting a part of a specific monitoring lightsignal, an optical multiplexer for multiplexing the individual lightsignals outputted from the second fixed-gain optical amplifiers #1; #n,respectively, for thereby outputting multiplexed light signals, and anadjustable attenuator control circuit for detecting output power of themonitoring light branching device to thereby control the attenuationfactor of the optical attenuator so that the detected output powerassumes a constant value. By virtue of the arrangement described above,there can be provided the optical amplifying repeater apparatus whosegain exhibits essentially no dependency on the change of the number ofwavelengths. In other words, the optical amplifying repeater apparatushaving the communication quality which is essentially insusceptible tothe change in the number of the wavelengths can be realized. In theoptical amplifying repeater apparatus described above, there may beadopted such a system in which a tone signal of a specific frequency issuperposed on the monitoring light, wherein the tone signal is extractedin the optical attenuator control circuit for the purpose of eliminatingthe influence of noise.

Further, the optical amplifying repeater apparatus according to thepresent invention includes an input port to which a plurality of lightsignals multiplexed in wavelength are inputted, a first fixed-gainoptical amplifier for amplifying the wavelength-multiplexed lightsignals inputted through the input port with a predetermined gain, anoptical demultiplexer connected to output of the first fixed-gainoptical amplifier for demultiplexing the wavelength-multiplexed lightsignals into a plurality of individual light signals of respectivewavelengths, adjustable optical attenuators #1; #n for attenuating theoutputs of the optical demultiplexers, respectively, by a predeterminedfactor, fixed-gain optical amplifiers #1; #n for amplifying theplurality of light signals outputted from the adjustable opticalattenuators with a predetermined gain, monitoring light branchingdevices connected to outputs of the fixed-gain optical amplifiers #1; #nfor extracting parts of specific monitoring light signals #1; #n,respectively, an optical multiplexer for multiplexing the outputs of thefixed-gain optical amplifiers #1; #n to thereby output multiplexed lightsignals, and adjustable attenuator control circuits #1; #n for detectingoutput powers of the monitoring light branching devices to therebycontrol the attenuation factor of the optical attenuators so that eachof the detected output powers assumes a constant value. Owing to thearrangement described above, the gains of the optical amplifyingrepeater apparatus for the monitoring light wavelengths λ1n, . . . , λnnin the specific band can be determined. Thus, by employing as theoptical amplifying medium a substantially homogeneous medium such as asemiconductor amplifier, an optical fiber doped with a rare-earthelement or the like, the gains for the other wavelengths can be fixed,whereby the optical amplifying repeater apparatus whose gain exhibitssubstantially no dependency on the change in the number of thewavelengths can be realized.

In the optical amplifying repeater apparatus described above, the firstfixed-gain optical amplifier includes an optical fiber serving as atransmission line, a pumping light source for inducing stimulated Ramanamplifying action internally of the optical fiber in wavelength bands ofthe plurality of wavelength-multiplexed light signals, and an opticalcoupling device for coupling the output of the pumping light source withthe plurality of wavelength-multiplexed light signals. With thearrangement described above, the pumping light source activating thestimulated Raman amplifying operation is difficult to be subjected togain saturation when compared with the semiconductor amplifier and theoptical fiber doped with a rare-earth element and is capable ofperforming substantially linear operation up to the output powersubstantially equal to the pumping light power. In other words, thestimulated Raman amplifier is the most suitable amplifying medium to beused as the first fixed-gain optical amplifier. Thus, ideal operation ofthe first fixed-gain optical amplifier 1 can be realized.

Further, in the optical amplifying repeater apparatus described above,the first fixed-gain optical amplifier includes an optical fiber dopedwith a rare-earth element or alternatively a transition metal, a pumpinglight source for inducing amplifying action under stimulated emissioninternally of the optical fiber in wavelength bands of the plurality ofwavelength-multiplexed light signals, and an optical coupling device forcoupling the output of the pumping light source with the plurality ofwavelength-multiplexed light signals, wherein the optical fiber dopedwith the rare-earth element or alternatively the transition metal isoperative in an unsaturated region. Thus, by using the pumping lightsource of sufficiently high output power, constant gain can be ensuredfor the optical amplifying repeater apparatus independently of thenumber of the wavelengths as well as variance of loss in thetransmission line.

Further, in the optical amplifying repeater apparatuses described above,the fixed-gain optical amplifier #1; #n includes an optical amplifyingunit composed of an optical fiber doped with a rare-earth element oralternatively a transition metal and a pumping light source forstimulating the rare-earth element or alternatively the transition metalto thereby bring about stimulated emission, a compensating light sourcefor generating compensating light having a wavelength within anamplified wavelength band of the optical amplifying unit, ancompensating light coupling device for coupling the compensating lightwith the plurality of wavelength-multiplexed light signals, acompensating light branching device for separating mutually thecompensating light and the plural wavelength-multiplexed light signalscontained in the output of the optical amplifying unit, and acompensating light control circuit for controlling output power of thecompensating light source such that ratio between power of thecompensating light outputted from the compensating light branchingdevice and power of the compensating light outputted from thecompensating light source assumes a predetermined standard value. Withthe arrangement described above, the gain of the fixed-gain opticalamplifiers #1, . . . , #n at the wavelength of the compensating lightcan be regulated to be constant. Thus, for the doped fiber 1 havinghomogeneous characteristics, constant gain can be ensured for all thewavelength bands for amplification.

Furthermore, in the optical amplifying repeater apparatuses describedabove, the fixed-gain optical amplifier #1; #n includes an opticalamplifying unit composed of an optical fiber doped with a rare-earthelement or alternatively a transition metal and a pumping light sourcefor stimulating the rare-earth element or alternatively the transitionmetal to thereby bring about stimulated emission, and a compensatinglight control circuit for controlling output power of the compensatinglight source such that power of spontaneously emitted light outputtedfrom the optical amplifying unit assumes a predetermined standard value.With the arrangement described above, constant gain can be ensuredindependently of the number of the signal wavelengths injected orinputted to the optical fiber, since the gain of the optical fiber is inproportion to the power of spontaneously emitted light.

Furthermore, in the optical amplifying repeater apparatuses describedabove, the fixed-gain optical amplifier #1; #n includes an adjustableoptical attenuator #1′; #n′ inserted at an input or output side, wherebya means for changing the attenuation factor of the adjustable opticalattenuator #1′; #n′ in dependence on ambient temperature is implemented.With such arrangement, the gain of the optical fiber for the longestwave decreases as the temperature increases while the former increasesas the latter decreases, whereby the gain-wavelength characteristic inthe longest wave region can be maintained to be substantially constant.Besides, the absolute value of the gain can be held essentiallyconstant.

Additionally, the optical amplifying/repeating transmission systemaccording to the present invention includes a plurality of transmittersfor sending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system further includes a control signal superposing meansfor superposing a control signal of a specific frequency onto one of theplural light signals, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant. Thus, thereis realized the optical amplifying/repeating transmission system whichcan ensure a constant gain independently of the power of the inputsignal and the number of the wavelengths thereof.

Moreover, the optical amplifying/repeating transmission system accordingto the present invention includes a plurality of transmitters forsending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system further includes a control signal generating meansfor modulating one of the plural light signals with a control signal ofa specific frequency, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant. By virtue ofthe arrangement described above, there is realized the opticalamplifying/repeating transmission system which can ensure a constantgain independently of the power of the input signal and the number ofthe wavelengths thereof.

Further, the optical amplifying/repeating transmission system accordingto the present invention includes a plurality of transmitters forsending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system includes a control signal superposing means forsuperposing a control signal of a specific frequency onto one of theplural light signals, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant, a monitorsignal transmitting means for supplying transmission level of thecontrol signal to the optical repeater, and a monitor/control means forreceiving a monitoring signal supplied from the monitor signaltransmitting means to thereby enable the optical repeater gain controlmeans to operate when the level of the control signal is normal whiledisabling operation of the optical repeater gain control means with thegain thereof being held when the level of the control signal isabnormal. Thus, with the arrangement described above, themonitor/control circuit allows operation of the gain control system solong as the power of the light signal of wavelength λn is normal whilesuspending the operation of the gain control system by holding theattenuation factor of the adjustable optical attenuator to be constantwhen the power of the above wavelength is abnormal. By virtue of thisfeature, the gain of the optical repeater is prevented from being set toan erroneous value even when the power of the light signal of wavelengthλn lowers due to age deterioration or the like cause.

Furthermore, the optical amplifying/repeating transmission systemaccording to the present invention includes a plurality of transmittersfor sending out light signals of wavelengths differing one another andcarrying information, a plurality of receivers for receiving theplurality of light signals of mutually different wavelengths, and aplurality of optical repeaters installed between the transmitters andthe receivers for amplifying the plurality of light signals, and opticalfibers interconnecting the transmitters and the optical repeater, theplurality of optical repeaters, and the optical repeater and thereceivers, respectively, wherein the optical amplifying/repeatingtransmission system further includes a control signal generating meansfor modulating one of the plural light signals with a control signal ofa specific frequency, a control signal level detecting means connectedto the output of the optical repeater for extracting a part of outputpower of the optical repeater to thereby detect power of the controlsignal, and an optical repeater gain control means for controlling gainof the optical repeater so that level of the control signal detected bythe control signal level detecting means remains constant, a monitorsignal transmitting means for supplying transmission level of thecontrol signal to the optical repeater, and a monitor/control means forreceiving a monitoring signal supplied from the monitor signaltransmitting means to thereby enable the optical repeater gain controlmeans to operate when the level of the control signal is normal whiledisabling operation of the optical repeater gain control means with thegain thereof being held when the level of the control signal isabnormal. Thus, with the arrangement described above, themonitor/control circuit allows operation of the gain control system solong as the power of the light signal of wavelength λn is normal whilesuspending the operation of the gain control system by holding theattenuation factor of the adjustable optical attenuator to be constantwhen the power of the above wavelength is abnormal. By virtue of thisfeature, the gain of the optical repeater can be prevented from beingset to an erroneous value even when the power of the light signal ofwavelength in lowers due to age deterioration or the like cause.

In the optical communication system described above, the opticalrepeater gain control means is composed of an adjustable opticalattenuator and a means for controlling the adjustable opticalattenuator. Owing to this arrangement, there can be implemented theoptical amplifying/repeating transmission system which ensure a constantgain independently of the input signal power or the number of thewavelengths thereof with a simplified structure.

Further, in the optical communication system described above, thecontrol signal has a frequency higher than 100 kHz inclusive thereof. Byvirtue of this feature, stable amplification characteristics can beensured for the fixed-gain optical amplifier without inducing variationthereof.

Furthermore, in the optical communication system described above, themonitoring signal has a wavelength shorter than those sent out from theplurality of transmitters. By virtue of this feature, the operatingstate control of the gain control system can be performed even in theevent that the power of wavelength λn is interrupted for some reason.

Moreover, the optical amplifying repeater apparatus for amplifying aplurality of wavelength-multiplexed light signals according to thepresent invention includes a first fixed-gain optical amplifier foramplifying a plurality of wavelength-multiplexed light signals inputtedthereto with a predetermined gain, a control light signal branchingdevice for extracting a part of power of a control wavelength containedin the output of the first fixed-gain optical amplifier, an adjustableoptical attenuator for attenuating the output of the first fixed-gainoptical amplifier by a predetermined factor, an adjustable attenuatorcontrol circuit for detecting output power of the control light signalbranching device to thereby control the attenuation factor of theadjustable optical attenuator so that the detected output power remainsconstant, and a second fixed-gain optical amplifier connected to outputof the adjustable optical attenuator for amplifying the pluralwavelength-multiplexed light signal inputted to the second fixed-gainoptical amplifier with a predetermined gain. With the above arrangement,there can be realized the optical amplifying repeater apparatus havingthe gain which is independent of change of the number of wavelengths.

In the optical amplifying repeater apparatus described above further, anoutput breaking circuit for stopping amplifying function of the secondfixed-gain optical amplifier upon detection of disappearance of outputof the control light signal branching device is provided. With thisarrangement, it is possible to prevent the output power of the secondfixed-gain optical amplifier 4 from increasing abnormally even in theevent that the control light is interrupted for some cause.

What is claimed is:
 1. An optical amplifying repeater apparatus whereinthe apparatus comprises: an input port to which a plurality of lightsignals multiplexed in wavelength are inputted, a first fixed-gainoptical amplifier for amplifying the wavelength-multiplexed lightsignals inputted through said input port with a predetermined gain, anadjustable optical attenuator for attenuating the wavelength-multiplexedlight signals by a predetermined factor after amplification through saidfirst fixed-gain optical amplifier, an optical demultiplexer fordemultiplexing said wavelength-multiplexed light signals outputted fromsaid adjustable optical attenuator into a plurality of individual lightsignals of discrete wavelengths, respectively, more than one secondfixed-gain optical amplifiers for amplifying said plurality ofindividual wavelength-demultiplexed light signals outputted from saidoptical demultiplexer with a predetermined gain, a monitoring lightbranching device connected to one of outputs of said more than onesecond fixed-gain optical amplifiers for extracting a part of a specificmonitoring light signal, an optical multiplexer for multiplexing theindividual light signals outputted from said more than one secondfixed-gain optical amplifiers, respectively, for thereby outputtingmultiplexed light signals, and an adjustable attenuator control circuitfor detecting output power of said monitoring light branching device tothereby control the attenuation factor of said optical attenuator sothat said detected output power assumes a constant value.
 2. An opticalamplifying repeater apparatus set forth in claim 1, wherein said firstfixed-gain optical amplifier comprises an optical fiber serving as atransmission line, a pumping light source for inducing stimulated Ramanamplifying action internally of said optical fiber in wavelength bandsof said plurality of wavelength-multiplexed light signals, and anoptical coupling device for coupling the output of said pumping lightsource with said plurality of wavelength-multiplexed light signals. 3.An optical amplifying repeater apparatus set forth in claim 1, whereinsaid first fixed-gain optical amplifier comprises an optical fiber dopedwith a rare-earth element or alternatively a transition metal, a pumpinglight source for inducing amplifying action under stimulated emissioninternally of said optical fiber in wavelength bands of said pluralityof wavelength-multiplexed light signals, and an optical coupling devicefor coupling the output of said pumping light source with said pluralityof wavelength-multiplexed light signals, wherein said optical fiberdoped with said rare-earth element or alternatively said transitionmetal is operative in an unsaturated region.
 4. An optical amplifyingrepeater apparatus set forth in claim 1, wherein said more than onesecond fixed-gain optical amplifiers comprises: an optical amplifyingunit composed of an optical fiber doped with a rare-earth element oralternatively a transition metal and a pumping light source forstimulating said rare-earth element or alternatively said transitionmetal to thereby bring about stimulated emission, a compensating lightsource for generating compensating light having a wavelength within anamplified wavelength band of said optical amplifying unit, acompensating light coupling device for coupling said compensating lightwith said plurality of wavelength-multiplexed light signals, acompensating light branching device for separating mutually thecompensating light and the plurality wavelength-multiplexed lightsignals contained in the output of said optical amplifying unit, and acompensating light control circuit for controlling output power of saidcompensating light source such that ratio between power of thecompensating light outputted from said compensating light branchingdevice and power of the compensating light outputted from saidcompensating light source assumes a predetermined standard value.
 5. Anoptical amplifying repeater apparatus set forth in claim 1, wherein saidmore than one second fixed-gain optical amplifiers comprises: an opticalamplifying unit composed of an optical fiber doped with a rare-earthelement or alterrfatively a transition metal and a pumping light sourcefor stimulating said rare-earth element or alternatively said transitionmetal to thereby bring about stimulated emission, and a compensatinglight control circuit for controlling output power of a compensatinglight source such that power of spontaneously emitted light outputtedfrom said optical amplifying unit assumes a predetermined standardvalue.
 6. An optical amplifying repeater apparatus set forth in claim 4,wherein said more than one second fixed-gain optical amplifiersincludes: an adjustable optical attenuator inserted at an input oroutput side, whereby means for changing the attenuation factor of saidadjustable optical attenuator in dependence on ambient teminperature isimplemented.